Integrated man-portable wearable antenna system
A man-portable wearable antenna system to be worn by a wearer. The wearable antenna system comprises a helmet antenna, a vest antenna worn around the torso, a body antenna worn along the entire body, and a means for routing signals between one of the antennas and a communication device.
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This application is a continuation-in-part of U.S. patent application Ser. No. 10/677,189, entitled IMPROVED ULTRA-BROADBAND ANTENNA INCORPORATED INTO A GARMENT, filed on Oct. 2, 2003, now U.S. Pat. No. 6,972,725 which is a continuation-in-part of U.S. patent application Ser. No. 10/263,943, entitled ULTRA-BROADBAND ANTENNA INCORPORATED INTO A GARMENT WITH RADIATION ABSORBER MATERIAL TO MITIGATE RADIATION HAZARD, filed on Oct. 3, 2002, now U.S. Pat. No. 6,788,262, which is a continuation-in-part of U.S. patent application Ser. No. 10/061,639, entitled ULTRA-BROADBAND ANTENNA INCORPORATED INTO A GARMENT, filed on Jan. 31, 2002 and issued as U.S. Pat. No. 6,590,540 on Jul. 8, 2003, and which is herein incorporated by reference.
BACKGROUND OF THE INVENTIONThis invention relates generally to the field of antennas. More specifically, this invention relates to an integrated man-portable wearable antenna, comprising multiple antennas.
The Joint Tactical Radio System, a Department of Defense initiative to provide network connectivity across much of the radio frequency spectrum, requires ultra-broadband antenna capability—the ability to send or receive a signal at any frequency between 2 MHz and 2000 MHz. Because disruption of command, communications, and control is a paramount goal of snipers, reduction of the visual signature of an antenna is highly desirable. Therefore, a need exists for a broadband, man-carried antenna that does not have a readily identifiable visual signature.
For a more complete understanding of the integrated man-portable wearable antenna system, reference is now made to the following detailed description of the embodiments as illustrated in the accompanying drawings wherein:
A man-portable wearable antenna system 10 worn by a human wearer comprises vest antenna 20 (shown in
Referring now to
VHF antenna 30 comprises first and second VHF radio frequency (RF) elements 31 and 33, shorting strap 34, left shoulder strap 36, and right shoulder strap 38, all of which are attached to garment 22. VHF RF elements 31 and 33 are attached to garment 22 so that the RF elements are separated by VHF gap 32, having a distance D1. Generally, D1≦2.5 cm, although the scope of the invention includes the distance D1 being greater than 2.5 cm as may be required to suit the requirements of a particular application. When RF energy is input, a voltage difference is generated across VHF gap 32.
VHF feed region 49 of VHF antenna 30 is shown in
Still referring to
Front UHF feed region 59 of UHF antenna 50 is shown in
Back UHF feed region 69 of UHF antenna 50 is shown in
As shown in
Referring now to
VHF feed region 49, UHF feed regions 59 and 69, and HF feed regions 79, shown in
In one embodiment of man-portable wearable antenna system 10, VHF antenna 30 and UHF antenna 50 of vest antenna 20 and upper portion 71 of body antenna 70 are integrated into military flak vest 11. As shown in
Now referring to
RF elements 82 and 83 are mounted to an electrically insulating liner 85, which serves as a supporting substrate for RF elements 82 and 83. Liner 85 may, for example, be made of cotton, polyester, or other dielectric material that may be woven or non-woven and shaped to fit over helmet 81. RF elements 82 and 83 may be attached to liner 85, as for example, by being sewn or glued. RF elements 82 and 83 may also be attached directly to helmets made of dielectric material without any intervening liner. Helmet 81 may be implemented as any type of helmet, including combat and construction helmets.
RF elements 82 and 83 are separated by a gap 84 having a distance D3 when helmet antenna 80 is fitted over helmet 81. Gap 84 provides a voltage difference between RF elements 82 and 83 when helmet antenna 80 is excited by RF energy. In typical applications, D3≦1.0 cm, although the scope of the invention includes gap 84 having a distance greater than 1.0 cm as may be required to suit the requirements of a particular application.
Still referring to
Now referring to
The impedance of the head of the person wearing helmet 81 affects the impedance of helmet antenna 80. In order to facilitate finely matching the impedance of helmet antenna 80 with an external electronic device (not shown), an impedance matching circuit 97 may be connected between RF feed 95 and patch 89 that is electrically connected to RF element 82.
Referring to
Clearly, many modifications and variations of the integrated man-portable wearable antenna system are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the integrated man-portable wearable antenna and method for fabricating the same may be practiced otherwise than as specifically described.
Claims
1. A man-portable wearable antenna system to be worn by a wearer, comprising:
- a helmet antenna worn on the head of said wearer, wherein said helmet antenna transmits and receives signals over a frequency range of 500 MHz through 2500 MHz;
- a vest antenna worn around the torso of said wearer, wherein said vest antenna transmits and receives signals over a frequency range of 30 through 500 MHz;
- a body antenna worn along the entire body of said wearer, wherein said body antenna transmits and receives signals over a frequency range of 2 MHz through 30 MHz; and
- a means for routing signals between one of said antennas and a communication device.
2. The man-portable wearable antenna system of claim 1, wherein said helmet antenna comprises:
- a liner shaped to fit over a helmet;
- a first helmet RF element attached to said liner;
- a second helmet RF element attached to said liner so that said first and second helmet RF elements are separated by a gap;
- a helmet RF feed electrically connected to said first helmet RF element for providing energy to said first helmet RF element;
- a helmet ground feed electrically connected to said second helmet RF element;
- a first helmet shorting strap electrically connected to said first and second helmet RF elements opposite from said helmet RF feed; and
- a second helmet shorting strap electrically connected to said first and second helmet RF elements between said first helmet shorting strap and said helmet RF feed.
3. The man-portable wearable antenna system of claim 2, wherein said first and second helmet RF elements are made of a flexible electrically conductive material.
4. The man-portable wearable antenna system of claim 1, wherein said vest antenna comprises:
- an electrically nonconductive garment having anterior and dorsal regions, left and right shoulder regions, left and right side regions;
- a VHF antenna, comprising: a first VHF RF element attached to said garment; a second VHF RF element attached to said garment so that first and second VHF RF elements are separated by a gap; a VHF RF feed electrically connected to said first VHF RF element on said dorsal region of said garment for providing energy to said first VHF RF element; a VHF ground feed electrically connected to said second VHF RF element; a VHF shorting strap for providing an electrical connection between said first and second VHF RF elements on said anterior region of said garment; first and second shoulder straps electrically connected between said anterior and said dorsal regions of said first VHF RF element and which extend over said left and right shoulder regions of said garment; and a matching circuit electrically connected between said first VHF RF element and said VHF RF feed;
- a UHF antenna, comprising: a first front UHF RF element attached to said anterior region of said garment; a second front UHF RF element attached to said anterior region of said garment so that first and second front UHF RF elements are separated by a gap; a front UHF RF feed electrically connected to said first front UHF RF element for providing RF energy to said first front UHF RF element; a front UHF ground feed electrically connected to said second front UHF RF element; a first back UHF RF element attached to said dorsal region of said garment; a second back UHF RF element attached to said dorsal region of said garment so that first and second back UHF RF elements are separated by a gap; a back UHF RF feed electrically connected to said first back UHF RF element for providing RF energy to said first back UHF RF element; a back UHF ground feed electrically connected to said second back UHF RF element; at least one first connecting wire electrically connected between said first front and said first back UHF RF elements; at least one second connecting wire electrically connected between said second front and said second back UHF RF elements.
5. The man-portable wearable antenna system of claim 4, wherein said electrically nonconductive garment comprises a flak vest.
6. The man-portable wearable antenna system of claim 4, wherein said first and second VHF RF elements, said first and second front UHF RF elements, and said first and second back UHF RF elements are made of a flexible electrically conductive material.
7. The man-portable wearable antenna system of claim 1, wherein said body antenna comprises:
- a first electrically nonconductive garment to be worn about the upper body of said wearer having anterior and dorsal regions, left and right side regions;
- first and second conductive elements attached to said first electrically nonconductive garment, wherein said first conductive element extends substantially along said left side region to said dorsal region of said first garment and said second conductive element extends substantially along said right side region to said dorsal region of said first garment;
- a HF RF feed attached to said dorsal region of said first electrically nonconductive garment, said HF RF feed electrically connected to said first conductive element for providing RF energy to said first conductive element;
- a HF ground feed electrically attached to said second conductive element;
- a second electrically nonconductive garment to be worn about the lower body of said wearer having left and right side regions;
- first and second longitudinal conductive strips having top and bottom ends attached along said left and right side regions of said second electrically nonconductive garment, wherein said first and second longitudinal conductive strips extend substantially along the length of said second garment and vertically when said wearer is in a standing position and said top ends are attached to said first and second conductive elements; and
- first and second conductive inserts for lining the inners sole of footwear to be worn by said wearer attached to said bottom ends of said first and second longitudinal conductive strips.
8. The man-portable wearable antenna system of claim 7, wherein said first electrically nonconductive garment comprises a flak vest.
9. The man-portable wearable antenna system of claim 7, wherein said conductive elements, longitudinal conductive strips, and conductive inserts are made of a flexible electrically conductive material.
10. The man-portable wearable antenna system of claim 1 wherein said means for routing signals between one of said antennas and a communication device comprises a switch.
11. The man-portable wearable antenna system of claim 1 wherein said means for routing signals between one of said antennas and a communication device comprises a quadraplexer.
12. A method for forming a man-portable wearable antenna system to be worn by a wearer, comprising the steps of:
- forming a helmet antenna to be worn on the head of said wearer, wherein said helmet antenna transmits and receives signals over a frequency range of 500 MHz through 2500 MHz;
- forming a vest antenna to be worn around the torso of said wearer, wherein said vest antenna transmits and receives signals over a frequency range of 30 through 500 MHz;
- forming a body antenna to be worn along the entire body of said wearer, wherein said body antenna transmits and receives signals over a frequency range of 2 MHz through 30 MHz; and
- providing a means for routing signals between one of said antennas and a communication device.
13. The method of claim 12, wherein said step of forming a helmet antenna comprises the steps of:
- attaching a first helmet RF element to a liner shaped to fit over a helmet;
- attaching a second helmet RF element to said liner so that said first and second helmet RF elements are separated by a gap;
- connecting a helmet RF feed to said first helmet RF element for providing energy to said first helmet RF element;
- connecting a helmet ground feed to said second helmet RF element;
- attaching a first helmet shorting strap to said first and second helmet RF elements opposite from said helmet RF feed, for providing an electrical connection between said first and second helmet RF elements; and
- attaching a second helmet shorting strap to said first and second helmet RF elements between said first helmet shorting strap and said helmet RF feed.
14. The method of claim 12, wherein said step of forming a vest antenna comprises the steps of:
- forming a VHF antenna on an electrically nonconductive garment having anterior and dorsal regions, left and right shoulder regions, left and right side regions, wherein said step of forming a VHF antenna comprises the steps of; attaching a first VHF RF element to said garment; attaching a second VHF RF element to said garment so that first and second VHF RF elements are separated by a gap; connecting a VHF RF feed to said first VHF RF element on said dorsal region of said garment for providing energy to said first VHF RF element; connecting a VHF ground feed to said second VHF RF element; attaching a VHF shorting strap to said first and second VHF RF elements on said anterior region of said garment; connecting first and second shoulder straps between said anterior and said dorsal regions of said first VHF RF element and extending over said left and right shoulder regions of said garment; and connecting a matching circuit between said first VHF RF element and said VHF RF feed;
- forming a UHF antenna on said electrically nonconductive garment, wherein said step of forming a UHF antenna comprises the steps of: attaching a first front UHF RF element to said anterior region of said garment;
- attaching a second front UHF RF element to said anterior region of said garment so that first and second front UHF RF elements are separated by a gap; connecting a front UHF RF feed to said first front UHF RF element for providing RF energy to said first front UHF RF element; connecting a front UHF ground feed to said second front UHF RF element; attaching a first back UHF RF element to said dorsal region of said garment; attaching a second back UHF RF element to said dorsal region of said garment so that first and second back UHF RF elements are separated by a gap; connecting a back UHF RF feed to said first back UHF RF element for providing RF energy to said first back UHF RF element; connecting a back UHF ground feed to said second back UHF RF element; attaching at least one first connecting wire between said first front and said first back UHF RF elements; and attaching at least one second connecting wire between said first front and said first back UHF RF elements.
15. The method of claim 12, wherein said step of forming a body antenna comprises the steps of:
- attaching first and second conductive elements to a first electrically nonconductive garment to be worn about the upper body of said wearer having anterior and dorsal regions, left and right side regions, wherein said first conductive element extends substantially along said left side region to said dorsal region of said first garment and said second conductive element extends substantially along said right side region to said dorsal region of said first garment;
- attaching a HF RF feed to said dorsal region of said first electrically nonconductive garment;
- connecting said HF RF feed to said first conductive element for providing RF energy to said first conductive element;
- connecting a HF ground feed to said second conductive element;
- attaching first and second longitudinal conductive strips having top and bottom ends to a second electrically nonconductive garment to be worn about the lower body of said wearer having left and right side regions, wherein said first and second longitudinal conductive strips are attached along said left and right side regions of said second garment and extend substantially along the length of said second garment and vertically when said wearer is in a standing position and said top ends are attached to said first and second conductive elements; and
- attaching first and second conductive inserts for lining the inners sole of footwear to be worn by said wearer to said bottom ends of said first and second longitudinal conductive strips.
Type: Grant
Filed: Aug 26, 2004
Date of Patent: Feb 21, 2006
Assignee: The United States of America as represented by the Secretary of the Navy (Washington, DC)
Inventors: Richard C. Adams (Chula Vista, CA), Robert J. O'Neil (San Diego, CA), Jovan E. Lebaric (Carmel, CA), Todd R. Emo (Okinawa)
Primary Examiner: Hoanganh Le
Attorney: Peter A. Lipovsky
Application Number: 10/927,223
International Classification: H01Q 1/12 (20060101);